Anode and high-speed plating machine provided with the same

ABSTRACT

Providing an anode capable of desirably performing plating for a long period of time. An anode is cylindrical and forms a space between an article to be plated and itself. A plating solution flows in the space. Positive voltage is applied to the anode. The anode includes an outer cylinder and an inner cylinder welded to be in contact with an inner surface of the outer cylinder. The inner cylinder is formed of a plate material made from platinum.

TECHNICAL FIELD

The present invention relates to an anode and a high-speed platingmachine provided with the same.

BACKGROUND ART

Undermentioned Patent Document 1 discloses a conventional high-speedplating machine. The high-speed plating machine includes a closedcontainer constructed of a metal cylinder serving as an anode and lidmembers integrally connected to both ends of the metal cylinderrespectively. The metal cylinder is made from copper and has an innersurface and end surfaces on all of which thin films of platinum aredeposited respectively. The two opposed lid members are provided withrespective insertion holes through which plug members are slidinglyinserted. The plug members hold an article to be plated, therebetweenand constitute a part of a holding device. The plug members also serveas power supplying members which are brought into contact with thearticle to apply negative voltage to the article.

The high-speed plating machine also includes a power-supply unit whichenergizes the metal cylinder and the plug members so that positivevoltage is applied to the metal cylinder and the negative voltage isapplied to the article to be plated. The high-speed plating machinefurther includes a circulation unit which comprises a pump circulating aplating solution so that the plating solution flows in the closedcontainer.

In the high-speed plating machine, the article to be plated held betweenthe plug members is put into the closed container and the pump is thendriven so that the plating solution flows in the closed container. Thepositive voltage is applied to the metal cylinder and the negativevoltage is applied via the plug members to the article, with the resultthat a high-speed plating can be carried out with a plating time beingreduced.

PRIOR ART DOCUMENTS Patent Documents

Patent Document 1: Japanese Patent Application Publication No.JP-A-S55-138097

SUMMARY OF THE INVENTION Problem to Be Overcome By the Invention

However, since the high-speed plating machine disclosed in Patentdocument 1 performs the plating with a larger current density ascompared with general plating machines, the thin platinum filmselectrodeposited on the inner surface of the metal cylinder aresometimes peeled off or wasted in a short time period. Uniform platingcannot be carried out when the thin platinum films electrodeposited onthe inner surface of the metal cylinder are peeled off or wasted. Thisincreases a replacement frequency of the metal cylinder and costs foradditional processing of thin platinum films in the high-speed platingmachine.

The present invention was made in view of the foregoing circumstancesand a subject matter to be overcome is to provide an anode which canperform a desirable plating for a longer period of time and also toprovide a high-speed plating machine provided with the anode.

Means for Overcoming the Problem

An anode of the present invention is cylindrical and forms a spacebetween an article to be plated disposed therein and itself, in whichspace a plating solution flows. Positive voltage is applied to theanode. The anode includes an electrically conductive outer cylinder andan inner cylinder welded to be in contact with an inner surface of theouter cylinder. The inner cylinder is formed of a plate material madefrom platinum.

Effect of the Invention

In the anode, since the inner cylinder formed of the plate material madefrom platinum is welded to the inner surface of the outer cylinder, theinner cylinder can strongly adhere closely to the electricallyconductive outer cylinder. This can prevent peel-off of the innercylinder formed of the platinum plate material from the inner surface ofthe outer cylinder during a plating process. Further, since the innercylinder is formed of the platinum plate material, a consumption ofplatinum by execution of electroplating can be rendered smaller than athin film of electrodeposited platinum. Thus, this anode can reduce areplacement frequency of the anode and additional processing costs.

Accordingly, the anode and the high-speed plating machine provided withthe anode can perform plating in good condition for a long period oftime.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a sectional view of a high-speed plating machine taken along amoving direction of a second power-supplying member of the high-speedplating machine according to an embodiment;

FIG. 2 is a sectional view of the high-speed plating machine taken alonga moving direction of a holding member of the high-speed platingmachine;

FIGS. 3(A) and 3(B) are, (A) a sectional view of an anode showing a flatplate material made from titanium and a flat plate material made fromplatinum, both of which are welded together, and (B) a sectional view ofthe anode made by rounding the plates into a cylindrical shape andbutting and welding both ends, respectively;

FIG. 4 is a sectional view of the anode and a first power-supplyingmember;

FIG. 5 is an enlarged sectional view of a part of the high-speed platingmachine located above an upper part of the anode;

FIG. 6 is an enlarged sectional view of a lower receiving membersupporting a lower part of the anode and the periphery of the lowerreceiving member;

FIG. 7 is a top plan view of the high-speed plating machine;

FIG. 8 is a horizontal sectional view of a part of the high-speedplating machine, showing second power-supplying members;

FIG. 9 is a partial sectional view of the second power-supplying member;

FIG. 10 is a horizontal sectional view of a part of the high-speedplating machine, showing the holding member;

FIG. 11 is a sectional view of the high-speed plating machine takenalong the moving direction of the second power-supplying members,showing the state before an article to be plated is lowered into theanode;

FIG. 12 is a sectional view of the high-speed plating machine takenalong the moving direction of the holding member, showing the statebefore the article to be plated is lowered into the anode;

FIG. 13 is a sectional view of the high-speed plating machine takenalong the moving direction of the second power-supplying members,showing the state in which a lower end of the article has been insertedinto an upper end recess of a support rod;

FIG. 14 is a sectional view of the high-speed plating machine takenalong the moving direction of the second power-supplying members,showing the state in which the article has been lowered into the anode;

FIG. 15 is a sectional view showing distal ends of the secondpower-supplying members brought into contact with a periphery of thearticle;

FIG. 16 is a sectional view of the high-speed plating machine takenalong the moving direction of the holding member, showing the state inwhich the article has been held by the holding member;

FIG. 17 is a horizontal sectional view showing the article held by theholding member; and

FIG. 18 is an enlarged view of a part of the high-speed plating machinelocated above the upper part of the anode, showing the article held bythe holding member.

MODE FOR CARRYING OUT THE INVENTION

An embodiment of the high-speed plating machine provided with the anodeof the present invention will be described with reference to thedrawings.

The high-speed plating machine of the embodiment includes an anode 10, afirst power-supplying member 20 which is brought into contact with theanode 10 to apply positive voltage to the anode 10, secondpower-supplying members 30 which are brought into contact with anarticle 1 to be plated serving as a workpiece to apply negative voltageto the article 1, a holding device 40 including holding members 41 whichhold the article 1, a pressurizing unit 50 supplying air into a holdingchamber 45 housing the holding members 41 thereby to pressurize anatmosphere in the holding chamber 45, a circulation unit 60 circulatinga plating solution, and a power supply unit 70 energizing the anode 10and the second power-supplying members 30, as shown in FIGS. 1 and 2.

The anode 10 is cylindrical in shape and is disposed to extend in avertical direction. The anode 10 has an outer cylinder 11 formed of aplate material made from titanium and an inner cylinder 12 formed of aplate material made from platinum, as shown in FIGS. 3 and 4. The anode10 also has ring members 13 made from titanium and fitted onto upper andlower ends thereof respectively, as shown in FIGS. 1 and 2.

The anode 10 is manufactured in the following manner. Firstly, a flatplate material 12A made from platinum is overlapped with a flat platematerial 11A made from titanium, and the overlapped sides are weldedtogether by electrical resistance welding, so that the plate materialsare manufactured into a double structure plate material 10A (see FIG.3(A)). Next, the double structure plate material 10A is rounded with theplatinum plate material 12A being located inside and then shaped into acylindrical shape. Both end faces of the material 10A are butted witheach other and welded together (see FIG. 3(B)). The ring members 13 arewelded onto outer peripheries of upper and lower ends of the anode 10thereby to be integrated with the anode 10.

Since the inner cylinder 12 comprised of the platinum plate material 12Ais welded onto an inner periphery of the electrically conductive outercylinder 11 made from titanium thereby to be formed into the anode 10,the inner cylinder 12 comprised of the platinum plate material 12A canbe attached firmly to the electrically conductive outer cylinder 11.This can reduce peel-off of the inner cylinder 12 comprised of theplatinum plate material 12A from the inner periphery of the outercylinder 11 during the plating process. Further, since the innercylinder 12 is formed of the platinum plate material 12A, an amount ofwear of platinum caused by electrical plating can be rendered smallerthan a thin film of electrodeposited platinum. This can reduce areplacement frequency of the anode 10 and additional processing costs.

Accordingly, the anode 10 and the high-speed plating machine providedwith the anode 10 can perform plating in good condition for a longperiod of time.

Further, the anode 10 is formed by overlapping the flat platinum platematerial 12A with the flat titanium plate material 11A and thereafter bybutting the end surfaces with each other and welding the end surfacestogether. As a result, the cylindrical anode 10 can easily be formedwhich is comprised of the outer cylinder 11 formed of the flat titaniumplate material 11A and the inner cylinder 12 formed of the flat platinumplate material 12A.

The first power-supplying member 20 is formed of a first member 21 and asecond member 22 as shown in FIGS. 1, 2 and 4. These are attached to apart of the anode 10 located between the ring members 13 fitted on theupper and lower ends of the anode 10. The first member 21 may be acopper plate, and the second member 22 may be a copper plate having asmaller thickness than the first member 21. The first member 21 may be alongitudinally long rectangular flat plate extending in an up-downdirection along the anode 10. The first member 21 has a horizontalmiddle part brought into contact with the outer periphery of the anode10 extending vertically linearly. The second member 22 may have two endsabutting against the first member 21 and may be a longitudinally longrectangular flat plate extending in an up-down direction along the anode10. The ends of the second member 22 are bolted to the first member 21by a plurality of bolts. The second member 22 has a middle part which isswollen frontward into a U shape so as to cover the anode 10 in a statewhere the second member 22 is bolted to the first member 21. The secondmember 22 also has an inner surface brought into contact with a halfcircumferential surface of the anode 10 which is located away from thefirst member 21. The anode 10 can be detached and thereby can bereplaced by loosening the bolts fastening the first and second members21 and 22.

The anode 10 has an upper end supported by an upper receiving member 80and a lower end supported by a lower receiving member 90, as shown inFIGS. 1 and 2. The upper receiving member 80 is fixed to a flatplate-shaped first fixing member 100 having an opening through which theanode 10 is inserted. The lower receiving member 90 is fixed to a flatplate-shaped second fixing member 101 having an opening through which asupport rod 15 which will be described later is inserted. The secondfixing member 101 is connected to four connecting members 102 extendingdownward from an underside of the first fixing member 100, so as to belocated below the first fixing member 100.

The upper receiving member 80 has an outer shape of rectangularparallelepiped and includes an upper space 81 open vertically upward anda lower space 82 continuous from a lower end of the upper space 81 andopen vertically downward, as shown in FIG. 5. The upper and lower spaces81 and 82 have respective inner peripheries which are concentricallycircular in horizontal cross-section. A base member 85 which will bedescribed later has a lower part inserted into the upper space 81 fromabove. Two second power-supplying members 30 are aligned and haverespective distal ends which are opposed to each other in a part of theupper space 81 located below the base member 85. The secondpower-supplying members 30 are disposed to be movable toward and awayfrom a center of the upper space 81. The upper space 81 has a platingsolution outlet 83 extending continuously horizontally thereby to beopen in a side surface of the upper receiving member 80, as shown inFIGS. 2 and 5. A generally L-shaped outflow pipe 61 is connected to theplating solution outlet 83.

The upper end of the anode 10 on which the ring member 13 is fitted isinserted into the lower space 82 of the upper receiving member 80, asshown in FIGS. 1, 2 and 5. Two corrosion-resistant O-rings R1 areinterposed between an inner periphery of the lower space 82 and an outerperiphery of the ring member 13. As a result, the plating solution canbe prevented from leaking through a connection of the lower space 82 ofthe upper receiving member 80 and the anode 10.

The lower receiving member 90 has an outer shape of rectangularparallelepiped and includes an upper space 91 open vertically upward anda lower space 92 continuous from a lower end of the upper space 91, asshown in FIG. 6. The upper and lower spaces 91 and 92 have respectiveinner peripheries which are concentrically circular in horizontalcross-section. The lower end of the anode 10 on which the ring member 13is fitted is inserted into the upper space 91. Two corrosion-resistantO-rings R2 are interposed between an inner periphery of the upper space91 and an outer periphery of the ring member 13. As a result, theplating solution can be prevented from leaking through a connection ofthe upper space 91 of the lower receiving member 90 and the anode 10.

The lower space 92 of the lower receiving member 90 has a platingsolution inlet 93 extending continuously in a horizontal direction andopen in a side surface of the lower receiving member 90, as shown inFIGS. 1, 2 and 6. An inflow pipe 62 is connected to the plating solutioninlet 93. Further, the lower space 92 also has an insertion hole 94extending continuously vertically downward and open in a lower endsurface of the lower receiving member 90. The insertion hole 94, thelower space 92 and the upper space 91 have respective inner peripherieswhich are concentrically circular in horizontal cross-section. Acolumnar support rod 15 is inserted through the insertion hole 94 so asto be movable upward and downward.

The support rod 15 has an upper end with a recess 16 open upward. Alower end of the columnar article 1 to be plated is inserted into therecess 16. The support rod 15 also has a lower end which is connected toa piston rod of an air cylinder (not shown). Accordingly, the supportrod 15 can be moved upward and downward on a central axis of the anode10 by driving the air cylinder. Two corrosion-resistant O-rings R3 and adust seal S1 are interposed between an inner periphery of the insertionhole 94 and the support rod 15. This can prevent dust from enteringinside from the outside as well as the plating solution from leakingthrough a gap between the insertion hole 94 and support rod 15.

The upper receiving member 80 has two opposed sides through each one ofwhich two through holes 84 extend linearly toward the upper space 81, asshown in FIGS. 1 and 8. The second power-supplying members 30 areinserted into the through holes 84 respectively. The secondpower-supplying members 30 are aligned as described above and haverespective distal ends opposed to each other in a part of the upperspace 81 located below the base member 85. The second power-supplyingmembers 30 have rear ends which are located outside the side surfaces ofthe upper receiving member 80 and are connected via gripping members 130to piston rods 111 of air cylinders 110, respectively, as shown in FIG.7. The air cylinders 110 are fixed to fixing walls 103 standing fromboth ends of the first fixing member 100 respectively. Accordingly, thesecond power-supplying members 30 are movable forward toward andbackward away from the center of the upper space 81 by driving the aircylinders 110. More specifically, the second power-supplying members 30are movable between respective forward positions toward the article 1disposed at the center of the upper space 81 and respective backwardpositions away from the article 1. The second power-supplying members 30have distal ends which are brought into contact with the outer peripheryof the article 1 when located at the forward positions, respectively.The distal ends of the second power-supplying members 30 are moved awayfrom the outer periphery of the article 1 when located at the respectivebackward positions. Substantially U-shaped power-supply plates 71 eachmade from copper have one ends which are connected to the grippingmembers 130 holding the rear ends of the second power-supplying members30, respectively. The power-supply plates 71 have the other endsconnected to each other by a copper-made connecting plate 72. Thepower-supply plates 71 are deformable to follow the forward or backwardmovement of the respective second power-supplying members 30. Thepower-supply plates 71 are further connected to a power supply 75.

Each one of the second power-supplying members 30 is formed into acolumnar shape and has a forward/backward movement directioncorresponding to an axial direction thereof. Two corrosion-resistantO-rings R4 are interposed between the outer periphery of eachpower-supplying member 30 and an inner periphery of each through hole84, as shown in FIG. 8. As a result, each second power-supplying member30 can smoothly be moved forward and backward with the plating solutionbeing prevented from leaking through a gap between each secondpower-supplying member 30 and the upper space 81 of the upper receivingmember 80.

Each second power-supplying member 30 has a distal end notched into a Vshape such that a middle part thereof or a valley of the V shape islocated backward relative to both sides thereof in a planar view, asshown in FIGS. 7 to 9. Each second power-supplying member 30 includes acolumnar center member 31 made from copper and a covering member 32 madefrom titanium and covering a periphery of the center member 31, as shownin FIG. 9. The center member 31 has a diameter ranging from 90% to 50%of an outer diameter of the covering member 32. Since a part of theupper space 81 located below the base member 85 is filled with theplating solution, a part of each second power-supplying member 30 wettedwith the plating solution is covered with the titanium covering member32. Accordingly, each second power-supplying member 30 has an improvedcorrosion resistance to the plating solution. Consequently, thereplacement frequency of the second power-supplying member 30 can bereduced. Further, since each second power-supplying member 30 includesthe copper-made center member 31 having a higher electrical conductivitythan titanium, each second power-supplying member 30 can suppress heatgeneration during power supply and can reduce temperature rise of theplating solution as compared with power-supplying members made from onlytitanium.

Accordingly, the second power-supplying members 30 and the high-speedplating machine provided with the second power-supplying members 30 canperform plating in good condition for a long period of time.

The second power-supplying members 30 will be manufactured as follows.Firstly, as shown in FIG. 9, the inner periphery of the covering member32 is threaded while a columnar insertion space into which the centermember 31 is insertable is defined in the covering member 32. A malethread having the same thread size as the covering member 32 is formedon the center member 31. The center member 31 is then screwed into theinsertion space of the covering member 32 and brazed in an insertionhole of the covering member 32, so that the second power-supplyingmembers 30 are manufactured. The center member 31 of each secondpower-supplying member 30 has a rear end exposed from the coveringmember 32. The exposed center member 31 is used as an energizing partwhich is connected to the power supply 75 to energize the secondpower-supplying members 30 via the gripping member 130.

The holding device 40 has a base member 85 including a lower partinserted into the upper space 81 of the upper receiving member 80 fromabove, as shown in FIGS. 2, 5 and 10. The lower part of the base member85 has a columnar outer shape. The base member 85 further includes anupper part having an outer shape which is a rectangular parallelepipedshape. The upper receiving member 80 also has an outer shape which is arectangular parallelepiped shape, and the upper receiving member 80 andthe base member 85 are combined with each other so that four sidesforming respective peripheral edges are parallel with each other, in aplanar view as viewed from above. A corrosion-resistant O-ring R5 isinterposed between an upper surface of the upper receiving member 80 anda surface of the base member 85 spreading horizontally from an upper endof a lower part of the base member 85. This can prevent the platingsolution from leaking through a gap between the upper receiving member80 and the base member 85.

The base member 85 has a housing part 86 which is open vertically upwardand has a central lower part with a communication hole 87 openvertically downward. The housing part and the communication hole 87 haverespective inner peripheries which are concentrically circular inhorizontal cross-section. The communication hole 87 has a diameter whichis smaller than that of the inner periphery of the communication hole 87and slightly larger than that of the article 1 to be plated, so that thearticle 1 can be inserted through the communication hole 87.

The housing part 86 houses a pair of holding members 41. A holdingchamber 45 is thus defined by the housing part 86 of the base member 85and a seal cover 88 closing an upper part of the base member 85. Theseal cover 88 has a disc-shaped upper surface 88A and a side surface 88Bextending downward from a peripheral edge of the upper surface 88A. Theupper surface 88A has an air inlet 89 extending therethrough. An airtube 52 has one of two ends which is connected to the air inlet 89 andthe other end which is connected to a compressor 51. The pressurizingunit 50 thus includes the compressor 51 and the air tube 52. The sealcover 88 can be moved by a moving apparatus (not shown) to a positionwhere the upper opening of the base member 85 is closed by the sealcover 88, at which position the seal cover 88 is downwardly pressed. AnO-ring R6 is interposed between the upper surface of the base member 85and undersides of side surfaces of the seal cover 88. This can preventair from leaking through a gap between the base member 85 and the sealcover 88.

The holding members 41 include holding member bodies 42 and abuttingparts 43 respectively. Each holding member body 42 is formed into ashape of semicircular column and includes a middle part which extendsalong an axis of flat surface and forms a recess 44A recessed into asemicircular column shape. The recess 44A is formed to be larger thanthe outer diameter of the columnar article 1 to be plated. The holdingmember bodies 42 are disposed so that the flat surfaces 44B are opposedto each other.

Each abutting part 43 is formed of a sponge sheet 46 which is formedinto a rectangular shape in a planar view as viewed from above, as shownin FIG. 10. The sponge sheet 46 is an elastic body with chemicalresistance. The sponge sheet 46 has a middle part of a longer sideformed with the semicircular notch which serves as the abutting part 43.Each abutting part 43 has a diameter smaller than the outer diameter ofthe columnar article 1 to be plated and abuts against the outerperiphery of the article 1. More specifically, each abutting part 43 isformed by cutting out the sponge sheet 46 into a similar figure which issmaller than a side geometry of the article 1. As a result, the abuttingpart 43 can closely abut against the outer periphery of the article 1.

The holding member bodies 42 have respective sides which are opposed toeach other and are each formed with two grooves 47A and 47B which extendhorizontally at two locations spaced away from each other in aheightwise direction in order to hold the sponge sheet 46 therein, asshown in FIG. 5. Two thin sponge sheets 46 are inserted into each one ofthe upper grooves 47A thereby to be held therein. A thick sponge sheet46 is inserted into each one of the lower grooves 47B thereby to be heldtherein.

The base member 85 has two sides perpendicular to sides of the upperreceiving member 80, into which sides the second power-supplying members30 are inserted, respectively, as shown in FIG. 10. Air cylinders 120are mounted on the two sides of the base member 85 respectively. Thebase member 85 has two through holes 85A which extend through the twosides thereof into the housing part 86 and through which piston rods 121of the air cylinders 120 are inserted, respectively. Two O-rings R7 areinterposed between inner peripheries of the insertion holes 85A andouter peripheries of the piston rods 121 respectively. As a result, aircan be prevented from leaking through gaps between the insertion holes85A and the piston rods 121 respectively.

The piston rods 121 of the air cylinders 120 have distal ends which areconnected to the holding member bodies 42 in the holding chamber 45 ofthe base member 85, respectively. The holding members 41 are configuredto be movable between respective backward positions and forwardpositions. When the holding members 41 are located at the respectivebackward positions, respective flat surfaces 44B of the holding memberbodies 42 and respective end surfaces of the sponge sheets 46 areseparated from each other, and parts of arc-shaped sides of the holdingmember bodies 42 are in abutment against the inner periphery of the basemember 85. When the holding members 41 are located at the respectiveforward positions, the opposed end surfaces of the sponge sheets 46 arein contact with each other, and the abutting parts 43 of the spongesheets 46 closely abut against respective portions of the outerperiphery of the article 1 at the same level from both sides of thearticle 1 thereby to hold the article 1 therebetween.

A corrosion-resistant O-ring R8 is interposed between the underside ofthe holding member body 42 and the bottom of the housing part 86 of thebase member 85, as shown in FIG. 5. As a result, the plating solutioncan be prevented from leaking through gaps between the holding memberbodies 42 and the base member 85.

The circulation unit 60 includes a circulation path 63, a platingsolution control tank 64 and a pump 65 as shown in FIGS. 1 and 2. Thecirculation path 63 has a generally L-shaped outlet pipe 61 connected tothe plating solution outlet 83 open to the side surface of the upperreceiving member 80 and an inlet pipe 62 connected to the platingsolution inlet 93 open to the side surface of the lower receiving member90. The plating solution control tank 64 and the pump 65 are provided inthe middle of the circulation path 63. Upon drive of the pump 65, thecirculation unit 60 can supply the plating solution in the control tank64 into the plating solution inlet 93 of the lower receiving member 90and can thereafter circulate the plating solution through the lowerreceiving member 90, the anode 10, the upper receiving member 80, andthe plating solution outlet 83 sequentially in this order and thenreturn the plating solution into the plating solution control tank 64.

The power supply unit 70 includes the power supply 75 which is connectedso as to apply positive voltage to the anode 10 via the firstpower-supplying member 20 and so as to apply negative voltage to thearticle 1 to be plated via the second power-supplying members 30, asshown in FIG. 1.

A plating process performed by the high-speed plating machine thusconstructed will now be described as follows.

Firstly, when the second power-supplying members 30 and the holdingmembers 41 are located at the respective backward positions and thesupport rod 15 is in the raised state, the high-speed plating machine ison standby for the lowering of the article 1 gripped in the upper endthereof by a chuck 5, as shown in FIGS. 11 and 12. The article 1 islowered from the upper opening of the base member 85, and the lower endof the article 1 is inserted into the recess 16 upwardly open at theupper end of the support rod 15, as shown in FIG. 13.

Further, the piston rod of the air cylinder (not shown) connected to thelower end of the support rod 15 is lowered with the lowering of thechuck 5 gripping the upper end of the article 1, so that the article 1is lowered to a plating position. More specifically, the article 1 isdisposed so that a space in which the plating solution flows is formedbetween the anode 10 and the article 1.

In this state, the piston rods 111 of the air cylinders 110 are movedforward which are connected via the gripping members 130 to the rearends of the second power-supplying members 30, respectively. Morespecifically, the second power-supplying members 30 are moved to therespective forward positions toward the article 1. The distal ends ofthe second power-supplying members 30 are brought into contact with theupper periphery of the article 1 to hold the article 1, as shown inFIGS. 14 and 15. At this time, the holding members 41 are located at therespective backward positions. The chuck 5 releases the article 1 fromthe gripped state, being raised upward.

Subsequently, the piston rods 121 of the air cylinders 120 connected tothe holding member bodies 42 of the holding members 41 are movedforward, respectively. More specifically, the abutting parts 43 of thesponge sheets 46 are moved to the forward positions where the abuttingparts 43 of the sponge sheets 46 closely abut against respectiveportions of the outer periphery of the article 1 at the same level fromboth sides of the article 1 thereby to hold the article 1 therebetween,as shown in FIGS. 16 and 17. Further, the opposed end surfaces of theother parts of the sponge sheets 46 also abut closely against eachother, so that the opposed flat surfaces of the holding member bodies 42are in contact with each other.

Next, the seal cover 88 is moved by the moving apparatus to a positionwhere the seal cover 88 closes the upper opening of the base member 85,as shown in FIGS. 1, 2 and 18. The seal cover 88 is pressed downward atthis position. The compressor 51 is then driven so that air is suppliedinto the air inlet 89 of the seal cover 88, thereby pressurizing theatmosphere in the holding chamber 45. In this case, the plating solutionis circulated in a manner as will be described later. The compressor 51is driven to supply air into the holding chamber 45 so that the holdingchamber 45 is maintained at an inner pressure equal to or higher than aninner pressure in the region (corresponding to a liquid tank) where theplating solution flows between the article 1 and the anode 10.

The article 1 is disposed on the axis of the anode 10 in this state.More specifically, the inner periphery of the anode 10 is spaced awayfrom the outer periphery of the article 1 lengthwise at a constantdistance, so that the plating solution flows into the space.

Next, the pump 65 of the circulation unit 60 is driven to supply theplating solution in the plating solution control tank 64 to the platingsolution inlet 93 of the lower receiving member 90 and thereafter tocirculate the plating solution through the circulation path 63, that is,sequentially through the lower receiving member 90, the anode 10, theupper receiving member 80 and the plating solution outlet 83 back intothe plating solution control tank 64. The plating solution flows betweenthe anode 10 and the article 1.

The first and second power-supplying members 20 and 30 are energized bythe power supply unit 70 so that positive voltage is applied to theanode 10 and negative voltage is applied to the article 1, wherebyhigh-speed plating is carried out.

Thus, when the high-speed plating machine carries out the high-speedplating, the abutting parts 43 of the holding device 40 closely abutagainst the outer periphery of the columnar article 1 at the same level.Each abutting part 43 is comprised of chemical-resistant elastic spongesheet 46. Further, the compressor 51 is configured to supply air topressurize the atmosphere in the holding chamber 45. Accordingly, theabutting parts 43 comprised of the sponge sheet 46 are pressed by thepneumatic pressure with the result that the abutting parts 43 canclosely adhere to the outer periphery of the article 1. Further, sincethe atmosphere in the holding chamber 45 is pressurized, the platingsolution tending to leak to the holding chamber 45 side throughinterfaces between the abutting parts 43 and the article 1 or betweenthe abutting parts 43 are pushed back by the pneumatic pressure. As aresult, the holding device 40 can reliably prevent the plating solutionfrom leaking from below the base member 85 into the housing part 86 ofthe base member 85. Further, since each abutting part 43 is comprised ofthe elastic sponge sheet 46, the abutting parts 43 can closely adhere tothe outer periphery of the article 1 even when an outer peripheralconfiguration of the article 1 changes. As a result, the holding device40 can deal with a plurality of types of articles. Still further, sincethe sponge sheet 46 formed into the abutting parts 43 ischemical-resistant, the abutting parts 43 can be prevented fromdeterioration by the plating solution with the result that leakage ofplating solution can be prevented for a long period of time.

Accordingly, the holding device 40 and the high-speed plating machineprovided with the holding device 40 can hold a plurality of types ofarticles to be plated and reliably prevent leakage of plating solution.

Upon completion of the high-speed plating, the first and secondpower-supplying members 20 and 30 are de-energized by the power supplyunit 70. Further, the pump 65 of the circulation unit 60 is also stoppedwith the result that the plating solution is discharged out of the anode10 to be stored in the plating solution control tank 64. The seal cover88 is then moved by the moving apparatus from the position where theupper opening of the base member 85 is closed to a retreat position. Theholding members 41 are then moved to the respective backward positions,the upper end of the article 1 is gripped by the chuck 5, and the secondpower-supplying members 30 are moved to respective backward positions.The article 1 is pushed upward by the support rod 15 while being pulledupward by the chuck 5, so that the article 1 is pulled out of the upperopening of the base member 85 with the result that the plating processis completed.

The present invention should not be limited by the foregoing embodimentdescribed above with reference to the drawings but the scope of theinvention involves the following embodiments.

(1) The anode is formed into the cylindrical shape in the foregoingembodiment. However, when an article with another shape is to be plated,the anode may be formed into a shape according to the shape of thearticle to be plated.

(2) The center members of the second power-supplying members areconnected to the covering member by the screw in the foregoingembodiment. However, the inner periphery of the insertion space of thecovering member and the outer periphery of the center member may each beformed into a tapered shape and the center member may be press fittedinto the insertion space of the covering member.

(3) The covering member of the second power-supplying member covers thecenter member in a range wider than the part wetted with the platingsolution. However, the covering member may cover at least the partwetted with the plating solution.

(4) The middle part of the long side of each sponge sheet is notchedinto the semicircular shape, and the notches serve as the abutting partsin the foregoing embodiment. However, the notched shape may be matchedwith the shape of the article. Further, no notches may be formed.

(5) The article is held by two holding members from two directions inthe foregoing embodiment. However, the article may be held by three ormore holding members so that the abutting parts closely abut against theouter periphery of the article at the same level.

(6) Two grooves holding the sponge sheets are provided at two heightwisespaced positions of the holding member bodies respectively in theforegoing embodiment. However, one, three or more grooves may beprovided.

(7) In the foregoing embodiment, one sponge sheet or two overlappedsponge sheets are inserted into the grooves of the holding member bodiesthereby to be held therein. However, three or more overlapped spongesheets may be inserted into the grooves thereby to be held therein.

EXPLANATION OF REFERENCE SYMBOLS

-   1 . . . article to be plated-   10 . . . anode-   11 . . . outer cylinder

11A . . . flat plate material made from titanium

-   12 . . . inner cylinder-   12A . . . plate material made from platinum-   30 . . . second power-supplying member (power-supplying member)-   60 . . . circulation unit-   70 . . . power supply unit

1. An anode which is cylindrical and forms a space between an article tobe plated disposed therein and itself, in which space a plating solutionflows, wherein positive voltage is applied to the anode, the anodecomprising: an electrically conductive outer cylinder; and an innercylinder welded to be in contact with an inner surface of the outercylinder, the inner cylinder being comprised of a plate material madefrom platinum.
 2. The anode according to claim 1, wherein the outercylinder and the inner cylinder are formed by overlapping and welding aflat plate material made from titanium and a flat plate made fromplatinum and bending the welded flat plate materials into a cylindricalshape with the flat plate material made from platinum being locatedinside.
 3. A high-speed plating machine comprising: an anode defined byclaim 1; a power-supplying member brought into contact with an articleto be plated to apply negative voltage to the article; a circulationunit configured to circulate a plating solution so that the platingsolution flows between the anode and the article disposed in an interiorof the anode; and a power supply unit configured to energize the articlevia the anode and the power-supplying member.
 4. A high-speed platingmachine comprising: an anode defined by claim 2; a power-supplyingmember brought into contact with an article to be plated to applynegative voltage to the article; a circulation unit configured tocirculate a plating solution so that the plating solution flows betweenthe anode and the article disposed in an interior of the anode; and apower supply unit configured to energize the article via the anode andthe power-supplying member.